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Real-Time Polymerase Chain Reaction Assays for Rickettsial Diseases Allen L. Richards, PhD Director, Rickettsial Diseases Department Naval Medical Research Center 503 Robert Grant Avenue Silver Spring, MD 20910-7500 (301) 319-7668; FAX (301) 319-7460 USA [email protected] ABSTRACT Introduction/Rationale: Arthropod-borne rickettsial diseases are found worldwide and have been the cause of significant amounts of suffering, disability and fatalities among both military and civilian populations throughout history. Because of the similarity to many infectious diseases in signs and symptoms rickettsial diseases are difficult to diagnose clinically. Moreover, due to the time it takes for antibodies to develop and the low concentration of rickettsial agents in the blood stream the diseases are also difficult to diagnose by laboratory methods. For that reason we have developed real-time PCR assays to detect rickettsial disease agents both at the genus and the species level. Methods: Real-time PCR assays were developed to identify: 1) pathogenic Rickettsia; 2) Rickettsia prowazekii and R. rickettsii, the etiological agents for epidemic typhus and Rocky Mountain spotted fever (RMSF) and potential BW agents; R. typhi and R. felis the flea-borne typhus disease agents and Orientia (formerly Rickettsia) tsutsugamushi the scrub typhus agent. The assays utilize molecular beacon probes, which fluoresce when they encounter the target DNA sequence. By manipulating the annealing temperature, and magnesium, probe and primer concentrations of the assays, the optimal conditions were determined. A panel of 22 strains of rickettsiae, 20 strains of orientiae and 19 species of non-rickettsial agents were used to determine the specificity of the assays. Plasmids encoding the target sequences were used to calculate the sensitivity of the assays. Results: The rickettsial real-time assays were found to be specific: Rickettsia assay only was positive for rickettsial and not other bacterial nucleic acid; R. prowazekii assay detected four strains of R. prowazekii, but not R. typhi, any of eight spotted fever rickettsiae, O. tsutsugamushi or 11 non-rickettsial bacteria. R. rickettsii assay detected two strains of R. rickettsii but not any other spotted fever or typhus rickettsiae. R. typhi and R. felis only reacted to the DNA extracted from R. typhi and R. felis. O. tsutsugamushi assay detected 20 strains of Orientia but did not react to 17 strains of Rickettsia or 19 species of unrelated bacteria. The sensitivity of the assays was quite good with detection routinely at the level of 3 to 10 copies per reaction. Conclusion: These real-time PCR assays were found to be capable of detecting rickettsial diseases agents quickly and with great sensitivity and specificity. Paper presented at the RTO HFM Symposium on “NATO Medical Surveillance and Response, Research and Technology Opportunities and Options”, held in Budapest, Hungary, 19-21 April 2004, and published in RTO-MP-HFM-108. RTO-MP-HFM-108 25 - 1 Real-Time Polymerase Chain Reaction Assays for Rickettsial Diseases 1.0 INTRODUCTION Arthropod-borne rickettsial diseases are found worldwide and have been the cause of significant amounts of suffering, disability and fatalities among both military and civilian populations throughout history. Because of the similarity to many infectious diseases in signs and symptoms rickettsial diseases are difficult to diagnose clinically. Moreover, due to the time it takes for antibodies to develop and the low concentration of rickettsial agents in the blood stream the diseases are also difficult to diagnose by laboratory methods. For that reason we have developed the very sensitive and specific real-time PCR assays to detect rickettsial disease agents. 1.1 Rickettsial Diseases Rickettsial diseases are caused by infection with obligate intracellular Gram negative bacteria transmitted by arthropod vectors (see Table I). Because of their obligate host cell requirement these rickettsial agents may not be grown up on artificial media, but must be grown in living cells such as those found in tissue culture, fertilized eggs or laboratory animals. Rickettsial diseases are similar in that they commonly produce high fever and severe headache in patients. Rash may be seen, especially in typhus, some of the spotted fever diseases and scrub typhus. Because the signs and symptoms of rickettsial diseases are not very distinctive they are often confused with many other infectious diseases (e.g. malaria, dengue and typhoid fever). The pathology of rickettsial diseases is associated with the infection of endothelial cells by the rickettsial agents, producing disease in potentially all organs and tissues of the body. The rickettsial diseases are normally self- limiting though they may be quite severe and life threatening illnesses. Antibiotics, such as one of the tetracyclines and chloramphenicol generally produce dramatic recuperative effects seen within 24-48 hours. However, antibiotic resistance has recently been reported, so new treatment modalities and/or vaccines need to be discovered (Strickman 1995, Watt; Corwin 1999). 1.2 Military importance of Rickettsial Diseases: Rickettsial diseases have played havoc on military operations throughout history (Rapmund, Kelly DJ 2002). The particular diseases and some of the outcomes of rickettsial diseases on military operations are given below. 1.2.1 Epidemic typhus Epidemic typhus is believed to be the “plague” that devastated Athens during the Peloponnesian War, and decimated Napoleon’s “Grande Armee” of 500,000 men that crossed the Nieman River into Poland to attack Russia in 1812. The Grande Armee returned to Poland in December with only 40,000 men. In addition to devastating military units, epidemic typhus commonly inflicts high morbidity and mortality upon poor, displaced and institutionalized populations (Raoult 1997, Raoult 1998, Tarasevich). During 1918-22 in Russia it is estimated that 2-3 million people (military and civilians during WWI and the Russia civil wars) died of typhus (Patterson). More recently (1997) in Burundi 45,558 typhus cases were diagnosed among the inhabitants during their country’s civil war (Raoult 1998). Because of epidemic typhus debilitating effects on military and civilian populations, it has been described as a potential BW agent (Eitzen). Moreover, due to its stability in dried feces of human body lice, its infection of humans by inhalation of aerosols, and the fact that just one organism can cause disease, R. prowazekii is considered a potential biological threat to be used by terrorists and rogue countries. This is more a concern now with the ability to produce in the laboratory antibiotic resistant strains, for which there is currently no FDA approved vaccine available to protect against (Kelly 2002). 1.2.2 Murine typhus Murine (endemic) typhus is commonly found throughout the world (Azad). However, it was not until the early 1900’s that murine typhus was determined to be a separate disease from epidemic typhus and therefore its impact on military operations was unknown through WWII. Since then, murine typhus has been found to 25 - 2 RTO-MP-HFM-108 Real-Time Polymerase Chain Reaction Assays for Rickettsial Diseases have been a major cause of fevers of unknown origin (FUO) during the Vietnam War, especially among US soldiers stationed in bases and cantonments (Azad). Because of its worldwide distribution, murine typhus is a potential threat to military deployments everywhere (Miller, Corwin 1997, Raoult 1998). 1.2.3 Spotted fever The spotted fevers group (SFG) include the agents that cause Rocky Mountain spotted fever (RMSF), Mediterranean spotted fever, African tick bite fever, Queensland tick typhus, and 10 other pathogenic and 20 other non-pathogenic rickettsiae. SFG rickettsiae have not caused major epidemics among military personnel similar to those associated with epidemic typhus. However in recent years, they have caused some significant outbreaks among U.S. military units training in CONUS and OCONUS and in one soldier returning from Somalia (Williams). During 1989, a military unit that trained in Arkansas and Virginia contracted RMSF. The seropositivity rate for those members that went only to Arkansas was 38% and for those that went just to Virginia was 13%. Forty-four percent of these individuals received medical treatment for their illnesses. In 1990, during exercises in Fort Chaffee, Arkansas, 30 individuals (n=1194) seroconverted to RMSF (Yevich). During a field-training mission in Botswana (1992), approximately 30% of 169 US soldiers sought medical attention due to an outbreak of African tick bite fever (Smoak). These outbreaks, the high exposure of military personnel to highly endemic areas and the rising incidence of RMSF at home (Treadwell) suggest that spotted fever diseases are a threat to military personnel training in tick-infested areas (Goddard). 1.2.4 Scrub typhus Scrub typhus is caused by infection with Orientia (formerly Rickettsia) tsutsugamushi. It occurs in Asia, northern Australia and the western Pacific region, an area in which approximately one million cases occur each year and over one billion people are at risk for contracting the disease. During WWII, scrub typhus was second only to malaria as a leading cause of lost man-days in the Pacific Theater and in some locations feared more than malaria because of a high mortality rate that could not be controlled (Rapmund). During the Vietnam War scrub typhus was a leading cause of FUO, especially among those individuals deployed
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